Department of Biochemistry, Hopkins Building, University of Cambridge, Tennis Court Road, Cambridge, CB2 1QW, United Kingdom.
Department of Biochemistry, Sanger Building, University of Cambridge, Tennis Court Road, Cambridge, CB2 1GA, United Kingdom.
Biochem Biophys Res Commun. 2023 Jul 23;666:61-67. doi: 10.1016/j.bbrc.2023.04.088. Epub 2023 May 2.
The RGD motif on the SARS-CoV-2 spike protein has been suggested to interact with RGD-binding integrins αVβ3 and α5β1 to enhance viral cell entry and alter downstream signaling cascades. The D405N mutation on the Omicron subvariant spike proteins, resulting in an RGN motif, has recently been shown to inhibit binding to integrin αVβ3. Deamidation of asparagines in protein ligand RGN motifs has been demonstrated to generate RGD and RGisoD motifs that permit binding to RGD-binding integrins. Two asparagines, N481 and N501, on the Wild-type spike receptor-binding domain have been previously shown to have deamidation half-lives of 16.5 and 123 days, respectively, which may occur during the viral life cycle. Deamidation of Omicron subvariant N405 may recover the ability to interact with RGD-binding integrins. Thus, herein, all-atom molecular dynamics simulations of the Wild-type and Omicron subvariant spike protein receptor-binding domains were conducted to investigate the potential for asparagines, the Omicron subvariant N405 in particular, to assume the optimized geometry for deamidation to occur. In summary, the Omicron subvariant N405 was primarily found to be stabilized in a state unfavourable for deamidation after hydrogen bonding with downstream E406. Nevertheless, a small number of RGD or RGisoD motifs on the Omicron subvariant spike proteins may restore the ability to interact with RGD-binding integrins. The simulations also provided structural clarification regarding the deamidation rates of Wild-type N481 and N501 and highlighted the utility of tertiary structure dynamics information in predicting asparagine deamidation. Further work is needed to characterize the effects of deamidation on spike-integrin interactions.
SARS-CoV-2 刺突蛋白上的 RGD 基序被认为与 RGD 结合整合素 αVβ3 和 α5β1 相互作用,以增强病毒细胞进入并改变下游信号级联。Omicron 亚变体刺突蛋白上的 D405N 突变导致 RGN 基序,最近已显示抑制与整合素 αVβ3 的结合。已经证明,蛋白配体 RGN 基序中的天冬酰胺脱酰胺会产生 RGD 和 RGisoD 基序,从而允许与 RGD 结合的整合素结合。野生型刺突受体结合域上的两个天冬酰胺,N481 和 N501,先前已显示脱酰胺半衰期分别为 16.5 和 123 天,这可能发生在病毒生命周期中。Omicron 亚变体 N405 的脱酰胺可能恢复与 RGD 结合整合素相互作用的能力。因此,本文对野生型和 Omicron 亚变体刺突蛋白受体结合域进行了全原子分子动力学模拟,以研究天冬酰胺(特别是 Omicron 亚变体 N405)是否有可能采用发生脱酰胺所需的优化几何形状。总之,发现 Omicron 亚变体 N405 主要通过与下游 E406 形成氢键而稳定在不利于脱酰胺的状态。然而,Omicron 亚变体刺突蛋白上的少数 RGD 或 RGisoD 基序可能恢复与 RGD 结合整合素相互作用的能力。模拟还提供了有关野生型 N481 和 N501 脱酰胺率的结构澄清,并强调了三级结构动力学信息在预测天冬酰胺脱酰胺中的效用。需要进一步的工作来表征脱酰胺对刺突-整合素相互作用的影响。
